KR920002015A - Hybrid Rice Production Using Perennial Male Infertile Rice - Google Patents

Abstract

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Description

Production of Hybrid Rice Using Perennial Male Rice Paste

As this is a public information case, the full text was not included.

3 is a partial view of a representative perennial cytoplasmic or genetically male paddy rice suitable for use in a preferred embodiment of the present invention.

4 is another exemplary perennial cytoplasmic or genetic male attachable partial view suitable in a preferred embodiment of the present invention.

5 is another exemplary perennial cellular or genetic male attachable partial view suitable for use in a preferred embodiment of the present invention.

Claims (33)

An improved method for producing a yearly ontogenic fertile F ₁ hybrid Oryza sativa plant, which is intended to consist of: (a) (i) a population of perennial magnetic fertility male paddy rice and (ii) 1) grow a year-old female fertility fertility population in a planting area that can restore fertility fertility to plants in subsequent generations produced by pollination of the population (i), and (b) from said population (i) to said population (i) Seeds capable of forming annually irritable fertility F ₁ hybrid Oryza sativa plants by pollinating pollen are produced on plants of said population (i), and seeds capable of forming seeds on plants of said population (ii) as a result of self pollination. (C) harvest the seeds produced in the plants of the populations (i) and (ii), and (d) substantially irrigate under atmospheric conditions while maintaining substantial growth. (Ii) killing plants that can restore fertility to plants produced by pollination of the plants of population (i) over subsequent winters, and (e) producing moisture from plants of surviving population (i). (Ii) a year-old female fertility fertile fermented rice population that is capable of restoring fertility to the plant is additionally planted in the planting area for subsequent growth, and (f) the additional population is added to the plant of the surviving population (i). (ii) produce seeds of the surviving population (i), which are capable of producing a yearly fertile fertility F ₁ hybrid Oryza sativa plant by pollination from the plants of (ii), and (g) the surviving population (i) and the population ( Harvest the seed produced in ii). The method of claim 1, wherein the perennial magnetic fertility paste (i) is characterized in that it has a cytoplasmic cohesion attachment. The method of claim 1, wherein the perennial fertility fermentation rice (i) is characterized in that it has a genetic fertility attachment. The method of claim 1, wherein in steps (a) and (e), said plants (i) and (ii) grow into a substantially heterogeneous population. 2. The method of claim 1, wherein in steps (a) and (e), the plants (i) and (ii) each grow into a substantially uniform population close to one another in water content. 6. The method according to claim 5, wherein in step (c) and (g), the seeds produced in the plants (i) and (ii) are selectively harvested, respectively. The method of claim 1, wherein in steps (a) and (e), one of said plants (i) and (ii) is indica and the other is japonica, increasing hybrid stress. The method of claim 1, wherein steps (d) to (g) are repeated one or more times after step (g). An improved method for producing seeds capable of progressively growing a _year-old aging fertility F ₁ hybrid Oryza sativa plant, characterized in that it comprises: (a) a substantially fully protruding ovule, a substantially fully protruding cone; Branches having a flag leaf that extends upwards to a maximum height lower than the tip of the cone without cutting, so that the cone is placed well to receive pollen from nearby plants, and the flag leaf is located below the tip of the cone. The population (i) is a population of perennial magnetic gyrozyme-bearing rice caused by a recessive cohort (i) and a population (ii) with elongated flag leaves due to a dominant gene that extends upwards to a maximum height higher than the tip of the cone. Annual fertility that can restore fertility in subsequent generations of plants by pollinating i) A population (ii) of adult fertile rice was grown in the recolored area, and (b) long polluted upwards to a maximum height greater than the end of the cone, by pollinating the population from the population (ii) to the population (i). Seeds produced in plants of the above-mentioned populations (i) and (ii) are harvested seeds capable of producing annually fertile fertility F ₁ hybrid Oryza sativa plants with flag leaves, and (d) the population (i). The plants of said population (ii) are exposed to such conditions and killed during the subsequent winter without substantially irrigating under atmospheric conditions, while retaining substantial growth, and (e) maximum greater than the end of the cone Restoration of spontaneous fertility to plants obtained by moistening additional populations (ii) with long upright flag leaves due to dominant genes extending upwards to the remaining populations (i) Additional populations of cultivable annual fertile fertile fermented rice (ii) were planted in the planting area for subsequent growth periods, and (f) pollinated the remaining population (i) with pollen from plants of the additional population (ii). To produce a seed on the remaining population (i) that has a flag leaf that extends upwards to a maximum height greater than the end of the cone, to produce an annual fertile fertile F ₁ hybrid Oryza sativa plant capable of effective photosynthesis. and (g) harvest the seeds produced in the remaining population (i) and the additional population (ii). 10. The method of claim 9, wherein the perennial fertility fermentation rice (i) is characterized in that it has a cytoplasmic cohesion. 10. The method of claim 9, wherein the perennial fertility fermentation rice (i) has a genetic fertility attachment. 10. The method according to claim 9, wherein the flag leaves of the perennial fertility fermented rice (i) are laid upside down due to recessive genes. 10. The method of claim 9, wherein in steps (a) and (e) the plants (i) and (ii) grow into a substantially heterogeneous population. 10. The method of claim 9, wherein in steps (a) and (e) the plants (i) and (ii) each grow in a uniform population close to pollination with each other. 10. The method of claim 9, wherein in steps (c) and (g), the plants (i) and (ii) selectively harvest the resulting seeds, respectively. 10. The method according to claim 9, wherein in steps (a) and (e), one of said plants (i) and (ii) is indica and the other is japonica, increasing hybrid stress. 10. The method of claim 9, wherein steps (d) to (g) are repeated one or more times after step (g). 10. The method of claim 9, wherein the perennial fertile fermented rice (i) also has the ability to form seeds associated with dominant genetic spatula markers; Also having the ability to generate seeds associated with recessive inherited genetic markers; harvesting in large quantities the seeds produced in said populations (i) and (ii) in steps (c) and (g); step (c) And (g) immediately following the seed generated in plant (ii) as a result of self-pollination of the seed capable of growing a yearly fertile fertile F ₁ hybrid Oryza sativa plant produced in plant (i) based on the genetic marker. A further step of separating. 19. The perennial female fertile fermented rice according to claim 18, wherein the perennial fertile fermented rice (i) has the ability to form related seeds of dominant inherited genetic markers in the form of a pale yellow shell. At the level having the ability to form seeds associated with recessive inherited markers in the form of gold husks. 19. The method of claim 18, wherein said seed is done using an optoelectronic seed sorting device. 10. The method of claim 9, wherein the perennial magnetic fertility paddy rice (i) has a pale colored leaves and ages of thermal inheritance, and the annual magnetic fertility paddy rice (ii) has a dark bicot and a hard bone, observed by the eye A method for identifying parental plants. It extends upwards to a maximum height that is substantially lower than the tip of the cone without cutting, substantially completely protruding, and its placement can produce related seeds of dominant genetic markers with flag leaves due to recessive genes. Oryza sativa seed product, characterized in that it consists of a substantially uniform set of seeds capable of yielding fertile perennial fertility cytoplasm. 23. The Oryza sativa seed product of claim 22, wherein said perennial female fertility cytoplasmic seed rice additionally has a cone that protrudes substantially completely without adding growth hormone. 24. The Oryza sativa seed product according to claim 23, wherein the seed is produced upon growth of perennial magnetic fertility cytoplasmic spp. With the flag leaf in an upside down arrangement. Opaquely protruding ovule, which extends upwards to a maximum height lower than the tip of the cone without cutting, the arrangement of which has flag leaves due to recessive genes, which can produce seeds associated with dominant markers. A binary Oryza sativa seed product, characterized in that it comprises a perennial female fertility genetically adapted rice (i) having a capacity and a seed that is produced upon growth of the perennial citron plant (2) to the plant (1). 26. The binary Oryza sativa seed product according to claim 25, wherein the plant (1) has an inverted sagging flag leaf due to a recessive gene. Perennial behavior, spores of periwinkle, substantially fully protruding ovules, extending upwards to a maximum height lower than the tip of the cone without cutting, the arrangement of which is caused by recessive genes, and dominant genetic markers Oryza sativa seed product, characterized in that it exhibits the ability to produce seeds associated with it. 28. The Oryza sativa plant of claim 27, additionally showing a conical cone that is substantially completely protruding without growth hormone. 28. The Oryza sativa plant according to claim 27, wherein said cohesiveness is cytoplasmic in trait. 28. The Oryza sativa plant according to claim 27, wherein the flag leaf exhibits an upside down locus caused by the forming gene. 28. The Oryza sativa plant according to claim 27, wherein said coercive adherence is genetic in character. 32. The Oryza sativa plant according to claim 31, wherein the flag leaf exhibits an upside down locus caused by the forming gene. ※ Note: The disclosure is based on the initial application.